Absolute and arbitrary orientation of single molecule shapes

TL;DR

This paper introduces a DNA origami technique that allows precise, absolute, and arbitrary orientation of nanoscale devices on surfaces, enabling improved integration and performance in nanotechnology applications.

Contribution

A novel DNA origami method that achieves unique, controllable orientation of single-molecule shapes on surfaces, facilitating large-scale, aligned device assembly.

Findings

Achieved 3.2° orientation precision on SiO₂ surfaces.

Demonstrated alignment of fluorescent dipoles within optical cavities.

Created an array of 3,456 origami with 12 distinct orientations.

Abstract

DNA origami is a modular platform for the combination of molecular and colloidal components to create optical, electronic, and biological devices. Integration of such nanoscale devices with microfabricated connectors and circuits is challenging: large numbers of freely diffusing devices must be fixed at desired locations with desired alignment. We present a DNA origami molecule whose energy landscape on lithographic binding sites has a unique maximum. This property enables device alignment within 3.2$^{\circ}$ on SiO$_2$. Orientation is absolute (all degrees of freedom are specified) and arbitrary (every molecule's orientation is independently specified). The use of orientation to optimize device performance is shown by aligning fluorescent emission dipoles within microfabricated optical cavities. Large-scale integration is demonstrated via an array of 3,456 DNA origami with 12 distinct orientations, which indicates the polarization of excitation light.